DE2445441B2 - Magnetic bubble domain device - Google Patents

Description

The invention relates to a magnetic bubble domain device according to the preamble of claim 1.

Such a device is known from US-PS 37 01 129. There are on a base a or several strips of blown domain material and electrical conductor tracks. Depends on the Direction of the currents in the conductor tracks can have different domains in the strip Sizes and different positions are set in the strip of bubble domain material. the However, the stability of the individual domain sizes and positions is not very great, especially in transport the domains by means of additional magnetic fields, so that by relatively small Disturbances, for example irregularities in the layer or in the external fields, are a domain of a certain shape or position, especially during transport, inadvertently a different shape or position can accept. Furthermore, in the known device, the or each strip of bubble domain material must have a precisely defined width that depends on the magnetic properties of the material depends. Training as a coherent simple layer is therefore not possible.

From U.S. Patents 3,728,153 and 3,676,872 devices are known in which bubble domains of different sizes are maintained and moved can be. However, these devices contain two layers of bubble domain magnetic materials different composition on top of each other. Due to the different material composition The magnetic properties of the layers are different and therefore also the Dimensions of the domains in the two layers. The structure of two layers requires one considerable manufacturing effort, and the domains of one size each serve to generate or Transporting the domains of the different size.

The object of the present application is to provide a magnetic bubble domain device of the initially mentioned specified type, which is simply built up from a single cohesive layer and in the the domains reliably maintain their size even during transport and a small spacing of the Domains without disturbing mutual influence is possible. According to the invention, this object is achieved by the features specified in the characterizing part of claim 1 solved.

With this device according to the invention it is possible in particular to provide a memory for binary data to build with high storage density. The difference between a bit 0 and a bit 1 now lies in the

ίο different sizes of domains. In a practical For example, the two domain sizes have the same shape and are, for example, both circular cylindrical designed. In another case, both domain sizes have different shapes, for example is one size circular cylindrical and the other size elongated. In each case, the one generated once Reliably maintain size through the domain line structure.

When using the device according to the invention as a memory for binary data, all neighboring bit positions are occupied. The repulsive interaction between the neighboring domains is only a function of the size of the domains to be taken into account is that there are only two types of domains in terms of size. As a result, the variation is the mutual interaction between domains at different locations in the device is very low. This makes it possible to maintain a smaller bit spacing, without the effect of the device being impaired

jo is affected. If the radius of the small circular cylindrical domains is R, a bit spacing of 3 /? To 4 R is possible in this case.

The two types of domains can be made in different ways. It is possible to use the device

J5 to be connected to two sources, each one generate certain domain type. It is also possible to use a single source, the one Can convert domain type to the other domain type. Should the stored information be changed or

<o If other information is to be processed, it should be new domains supplied from the source (s) and at least a part of those present in the device Domains discharged. Another possibility for generating the two types of domains is in claim 2 marked. One source of the device becomes a domain of a uniform type fed. In the latter case, when the information is changed, no new domains from a source are required fed and no domains present in the device to be discharged.

A domain movement structure is usually present on the layer for the transport of the domains. There are now various possibilities. So the domain line structure after the Invention and the domain locomotion structure on or on different sides of the layer Side of the layer. The domain line structure according to the invention and the Domains transport structure combined with each other

to be honored.

Embodiments of the invention are explained in more detail below with reference to the drawing. Show it

Figs. 1, 2 and 3 magnetic bubble domain devices; those with domain line structures for maintaining domains of different sizes and are each provided with a different domain movement structure,

Fig. 4a, 4b, 5a and 5b magnetic bubble domain

devices employing domain routing structures for maintaining domains of different sizes and are provided with conductor tracks for changing the size of the domains, and

F i g. 6 a magnetic bubble domain device; those with piner domain line structure to maintain domains of different sizes and with an arrangement for distinguishing these domains is provided.

In Fig. 1 is part of a plate! made of a magnetic bubble domain material. On the plate 1 there are two strips 2 and 3 made of a soft magnetic alloy with about 80% Ni, the remainder being Fe, of which the strip 2 is wider than the strip 3. These strips form the domain line structure. On the other surface of the plate 1 is a TI structure 4, also made of the soft magnetic alloy, which is indicated by dashed lines. With the aid of a magnetic field rotating in the plane of the plate 1 (which is generated by a device (not shown)), a magnetic domain 5 can be ^{displaced along de r} domain locomotion structure 4. The domain 5 is maintained by a certain magnetic field H perpendicular to the plane of the plate, in cooperation with the strip 2. The magnetic field H , in cooperation with the strips 2 and 3, maintains domains of larger dimensions than the domain 5, such as the one shown Domain 6, upright. The domain 6 can also be displaced along the structure 4 with the aid of the magnetic field rotating in the plane of the plate 1. In the example shown, the bit spacing 7 is equal to 4 /?, Where R is the radius of the small domain 5. For example, the plate 1 consists of Smo.jY2.7FeiKGa1.2O12 and has a thickness of 4.4 μm. r> The Sättigungsmagnetisation at room temperature is 9 x 10 ~ ⁴ T. The thickness of the soft magnetic strip 2 and 3 is 0.2 μιτι, and the domain movement structure 4 is 0.4 μηι. The width of the strip 2 is 8 μm, and that of the strip 3 is w 2.5 μm. The distance between the strips 2 and 3 is 1.5 μm. The bit distance 7 is 16 μΐη. The size of the field H for maintaining the domains is 1830 A / m and that of the rotating magnetic field is 2000 A / m. - * ■ »

In Fig. 2, part of a plate 11 made of a magnetic bubble domain material is shown. on the plate 11 ', ind three strips 12, 13 and 14 of soft magnetic material attached, one of which strip 12 is wider than strips 13 and 14. The strips 12, 13 and 14 form the domain line structure. On the other surface of the plate 11 is a herringbone structure 15, also made of wcirhmagnetic Material attached, which is indicated by dashed lines. With the help of a perpendicular to the plate 11 S5 The varying magnetic field generated by a device (not shown) is magnetic Domain 16 displaceable along structure 15. The domain 16 is perpendicular to the magnetic field Maintain the plane of the plate in t> o Working with the strip 12. The magnetic field perpendicular to the plane of the plate keeps working with the strip 12, 13 and 14 domains with larger dimensions than the domain 16, such as the Domain 17 shown, upright. The domain 17 is also with the help of the varying magnetic field displaceable along the structure 15.

In Fig. 3 shows part of a plate 21 made of magnetic bubble dome material. On the plate 21 lie two strips 22 and 23 made of soft magnetic material, of which the strip 22 has a greater width than the strip 23. These strips form the domain line structure. There is a strip 24 of gold thereon with a zigzag shape. At the location of the rising and falling branches of the strip 24, the wide strip 22 is provided with projections 25. With the aid of an electrical current through the strip 24, a magnetic domain 26 can be displaced along the strip 22. The projections 25 form an asymmetry which is necessary to determine the direction of movement. The domain 26 is maintained by a certain magnetic field H perpendicular to the plane of the disk, in cooperation with the strip 22. The magnetic field H in cooperation with the strips 22 and 23 holds domains of larger dimensions than the domain 26, such as that shown Domain 27, upright. The domain 27 can also be displaced through the strip 24 with the aid of an electric current.

4a shows part of a plate 31 made of magnetic bubble domain material. On the plate

31 there are two strips 32 and 33 of soft magnetic material, of which the strip

32 is wider than the strip 33. These strips form the domain line structure. A gold strip 34, which is U-shaped in the region of the strips 32 and 33, is attached thereon. Furthermore, a domain moving structure, not shown, is provided on one of the surfaces of the plate. On the strip 32, within the strip 34 in the plate 31, there is a circular magnetic domain 35 which is maintained by a certain magnetic field H perpendicular to the plane of the plate. If an electrical current pulse is passed through the strip 34, which has a polarity such that the magnetic field generated by the current within the U-shaped strip 34 is in a direction opposite to that of the external field H (and therefore the same direction as the magnetization of the domain 35) has, the domain becomes larger and has an elongated shape in the area of the strips 32 and 33, as indicated by 36 in FIG. 4b. The other designations are the same as in Fig. 4a. This domain 36 is maintained by the same magnetic field H. In the present example, the domain line structure (strips 32 and 33) and the strip 34 are on the same surface of the plate 31. It is also possible for these structures to be on different surfaces of the plate. In one example die_ plate 31 consists of Smo.jY2.7Fej.8Ga1.2O12 and has a thickness of 4.4 μm. The thickness of the soft magnetic strips 32 and 33 is 0.2 μm and that of the gold strip 34 is 0.3 μm. The width of the strip 32 is 8 μm and that of the strip 33 is 2.5 μm. The distance between the strips 32 and 33 is 1.5 μm. The width of the strip 34 is 2 μm and the distance between the two legs of the U is 8 μm. The size of the field H for maintaining the domains is 1830 A / m. The radius of the domain 35 is 4 μm. If a current of 12 mA is passed through the strip 34 for 1 | isec, the domain 35 changes into the domain 36 with dimensions of 12 μm 8 μm.

In Fig. 5a part of a plate 41 made of a magnetic bubble domain material is shown. on of the plate 41 are two strips 42 and 43 made of

soft magnetic material is present, of which the strip 42 is wider than the strip 43. A gold strip 44 which is U-shaped in the region of the strip 43 is attached thereon. Furthermore, a donut-advancing structure, not shown, is present on one of the surfaces of the plate. In the area of the strips 42 and 43, there is an elongated magnetic domain 45 partially within the legs of the U-shaped strip 44 in the plate 41, which is maintained by a certain magnetic field H perpendicular to the plane of the plate. If an electrical current pulse is now passed through the strip 44 which has such a polarity that the magnetic field generated by the current within the U-shaped strip 44 is directed in the same way as the external field H (and therefore directed in the opposite direction to the magnetization of the domain 45), in this way the domain becomes smaller and has a circular shape in the region of the strip 42, as is denoted by 46 in FIG. 5b. The other designations correspond to those in FIG. 5a. This domain 46 is maintained by the same magnetic field H. In one example, the plate 41 consists of Sinn iYi-Fej.nGa1.2O12 and has a thickness of 4.4 μm. The thickness of the strips 42 and 43 is 0.2 μm and that of the gold strip 44 is 0.3 μm. The width of the strip 42 is 8 μm and that of the strip 43 is 2.5 μm. The distance between the strips 42 and 43 is 1.5 μm. The width of the strip 44 is 2 μίτι. and the strip 44 is thus partially on the strip 43. The distance between the two legs of the U-shaped strip \ · Λ 8 μm. The size of the field H for maintaining the domains is 1830 A / m. The dimensions of the domain 45 are 12 μm χ 8 μm. If a current of 12 niA is passed through the strip 44 for 1 μϋΰΰ , the domain 45 changes into the circular domain 46 with a radius of 4 μm.

I "i g. Fc> shows part of a plate 51 from

magnetic bubble domain material. On the plate 51 lie two strips 52 and 53 made of soft magnetic material, 52 of which are wider than 53. A certain magnetic field H perpendicular to the plane of the plate, in cooperation with the strip 52, maintains domains with the size of the domain 54, while in cooperation with the strips 52 and 53 it maintains domains with the size of the domain 55. The domains are moved along the strip 52 or along the strips 52 and 53 with the aid of a domain moving structure (not shown). On the plate 51 is parallel to the strips 52 and 53 on the side of the narrow strip 53 a compared to the strips 52 and 53 very thin strip 56 of soft magnetic material is attached, which at the ends with existing on the plate 51 strips 57 and 58 of gold, which are partially located under the strip 56. The strips 56, 57 and 58 form part of the means for detecting the domains, the remaining parts of which are not shown. If a domain with the shape of domain 55 passes, a signal is induced in the detection device. If a domain with the shape of domain 54 passes, almost no signal is induced in the detection device. In this way it is possible to distinguish a 0 from a 1. In one example, the plate 51 consists of Sni (uYi.7FcijiGai.) Oi2 and has a thickness of 4.4 μm. The thickness of the strips 52 and 53 is 0.2 μm, that of the strip 56 is 0.04 μm and that of the gold strips 57 and 58 is 0.3 μm. The width of the strip 52 is 8 μm and that of the strip 53 is 2.5 μm. The distance between the strips 52 and 53 is 1.5 μm. The dimension of the strip 56 in the direction parallel to the strips 52 and 53 is 12 μm. The width of the strip 56 is 3 pm. The width of the strips 57 and 58 is 2 μm. The distance between the strips 56 and 53 is 1 μm.

For this purpose 2 sheets of drawing uncertainties

Claims (2)

Patent claims: 1. A magnetic bubble domain device comprising a layer of a magnetic bubble domain material; whose preferred direction is directed essentially perpendicular to the surface of the layer is in which magnetic bubble domains maintain at least two different sizes and can be moved, characterized in that that on the surface of the layer in the direction of movement of the bubble domains a domain line structure made of at least two parallel strips made of a soft magnetic one Material is arranged and that the domains of different sizes are different Extending numbers of strips. 2. Magnetic Blasendomänenvorrichtuwg according to claim 1, characterized in that on the Layer of electrical conductor tracks for converting domains of one size into the other are provided.